Abstract
The microstructure and geochemical composition of foraminiferal tests are valuable archives for the reconstruction of paleoclimatic and paleoecological changes. In this context, the late Miocene Globigerinoides obliquus shells from Faneromeni section (Crete Island) were investigated through Scanning Electron Microscopy (SEM) imaging, Energy Dispersive System (EDS) analysis and X-Ray Diffraction (XRD) spectroscopy in order to evaluate their potential as paleoenvironmental archives in the eastern Mediterranean. Investigation of diagenetic features, in late Miocene sediments from the Faneromeni section, shows that carbonate precipitation and cementation occur in various lithologies, particularly in carbonate-rich portions, such as bioclastic or clayey limestones. We identified 3 different diagenetic stages (early, intermediate, advanced), as a function of taphonomy in the study area. The comparison of microstructural and geochemical characteristics reveals a sequence of preservation states with “glassy” to “frosty” to “chalky” shells, indicative of the progressive diagenetic alteration of late Miocene planktic foraminiferal calcite. The early diagenetic stage occurs during the Tortonian, and consists of intermediates between “glassy” and “frosty” individuals. Around the Tortonian/Messinian (T/M) boundary at the second diagenetic stage, planktonic foraminifera have a clear “frosty” appearance, showing a gradual high-Mg calcite (to dolomite) crystal overgrowth development and dissolution of biogenic calcite. During the late Messinian and progressively through the Messinian Salinity Crisis (MSC), planktonic foraminifera present a “chalky” taphonomy. The additional precipitation of authigenic high-Mg inorganic calcite and dolomite crystals in the exterior of the tests characterizes the advanced diagenetic stage. The measured amount of diagenetic Mg-rich (10-14% molar Mg on average) calcite and/or dolomite coatings is compatible with results obtained on modern eastern Mediterranean core-top sediments. The assessment of such a diagenetic alteration contributes to a more precise reconstruction of sea surface temperatures (SSTs) during the Neogene, such that only when the changing proportions of the texture are accounted for, would geochemical measurements and subsequent paleoenvironmental interpretations be more meaningful. However, further investigations should extend this approach to test the robustness of our findings across a range of taphonomies, ages and burial settings.
Highlights
The Late Miocene has attracted recent interest as a potential model system for testing future climate change scenarios [1, 2]
The Messinian (7.24–5.33 Ma) has been considered as one of the most climatically stable periods of the Cenozoic, characterized by minor long-term cooling and ice growth [3]. These long-term trends are punctuated by the Messinian Salinity Crisis (MSC; 5.97–5.33 Ma), which has been attributed to changes in the carbon cycle, ocean circulation, and global sea level variations related to changing ice volume [4,5,6,7]
Inter-section variability in planktonic foraminiferal taphonomy The general view is that as carbonate sediments transition from marls to biogenic limestones, they undergo compaction, dissolution, recrystallization, and eventually cementation [46]
Summary
The Late Miocene has attracted recent interest as a potential model system for testing future climate change scenarios [1, 2]. In the last decade sustained and coordinated efforts focused on understanding the evolution of the Late Miocene MediterraneanAtlantic gateways and their impact on regional, and global environmental changes [14, 19]. In this context, recent advances in the application of geochemistry-based proxies (e.g. Mg/Ca, Sr/Ca, Ba/Ca, Uk’37, δ18O, GDGTs, clumped isotopes) offer novel, yet largely underexploited tools in unravelling fundamental climatic parameters like sea surface temperature (SST) and salinity (SSS) for the Mediterranean Sea during the pre-MSC to the Pliocene interval [20,21,22,23,24,25]. The full potential of Mediterranean sedimentary sequences as paleoclimate archives remains to be exploited because of problems with SST reconstructions in the Mediterranean Sea using wellcalibrated proxies coupled with improvements in analytical instrumentation (e.g. LA-ICPMS, FTTRA, SIMS), and assessing the diagenetic effect [26,27,28,29,30,31]
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More From: IOP Conference Series: Earth and Environmental Science
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